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		<id>https://en.formulasearchengine.com/w/index.php?title=Expected_value_of_including_uncertainty&amp;diff=26874</id>
		<title>Expected value of including uncertainty</title>
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		<summary type="html">&lt;p&gt;50.59.106.10: /* Example */&lt;/p&gt;
&lt;hr /&gt;
&lt;div&gt;[[Image:models osc.gif|right|200px|thumb|(a) The Brownian particle in the Caldeira-Leggett model experiences a fluctuating homogeneous field of force. (b) In case of the DLD model the fluctuating field is farther characterized by a finite correlation distance. The background image is a “snapshot” of the fluctuating environment. Namely, the gray levels correspond to the&lt;br /&gt;
“height” of an instantaneous potential which is experienced by the Brownian particle.]]&lt;br /&gt;
&lt;br /&gt;
A unified model for &#039;&#039;Diffusion Localization and Dissipation&#039;&#039; (DLD), optionally termed &#039;&#039;Diffusion with Local Dissipation&#039;&#039;, has been introduced for the study of &#039;&#039;Quantal Brownian Motion&#039;&#039; (QBM) in dynamical disorder&lt;br /&gt;
&amp;lt;ref&amp;gt;D. Cohen, Phys. Rev. E 55, 1422 (1997)&amp;lt;/ref&amp;gt;&lt;br /&gt;
.&amp;lt;ref&amp;gt;Phys. Rev. Lett. 78, 2878 (1997)&amp;lt;/ref&amp;gt; &lt;br /&gt;
It can be regarded as a generalization of the familiar [[Quantum_dissipation#The_Caldeira-Leggett_model|Caldeira-Leggett_model]].  &lt;br /&gt;
&lt;br /&gt;
&amp;lt;math&amp;gt;\mathcal{H} = \frac{p^2}{2m} + V(x) + \mathcal{H}_{int} + \mathcal{H}_{bath}&amp;lt;/math&amp;gt;&lt;br /&gt;
&lt;br /&gt;
&amp;lt;math&amp;gt;\mathcal{H}_{bath}=\sum_{\alpha}\left(\frac{P_{\alpha}^2}{2m_{\alpha}} +\frac{1}{2} m \omega_{\alpha}^2 Q_{\alpha}^2\right)&amp;lt;/math&amp;gt; &lt;br /&gt;
&lt;br /&gt;
&amp;lt;math&amp;gt;\mathcal{H}_{int} =  - \sum_{\alpha} c_{\alpha} Q_{\alpha} u(x-x_{\alpha})&amp;lt;/math&amp;gt;&lt;br /&gt;
&lt;br /&gt;
where &amp;lt;math&amp;gt;Q_{\alpha}&amp;lt;/math&amp;gt; denotes the dynamical coordinate of the &amp;lt;math&amp;gt;\alpha&amp;lt;/math&amp;gt;&lt;br /&gt;
scatterer or bath mode. &amp;lt;math&amp;gt;u(x-x_{\alpha})&amp;lt;/math&amp;gt; is the interaction potential, &lt;br /&gt;
and &amp;lt;math&amp;gt;c_{\alpha}&amp;lt;/math&amp;gt; are coupling constants. The spectral characterization of the bath &lt;br /&gt;
is analogous to that of the Caldeira-Leggett model:&lt;br /&gt;
&lt;br /&gt;
&amp;lt;math&amp;gt;\frac{\pi}{2} \sum_{\alpha} \frac{c^2_{\alpha}}{m_{\alpha}\omega_{\alpha}} \delta(\omega-\omega_{\alpha}) \ \delta(x-x_{\alpha}) \ = \ J(\omega)&amp;lt;/math&amp;gt;&lt;br /&gt;
&lt;br /&gt;
i.e. the oscillators that appear in the Hamiltonian are distributed uniformly over space, and in each location have the same spectral distribution &amp;lt;math&amp;gt;J(\omega)&amp;lt;/math&amp;gt;. &lt;br /&gt;
Optionally the environment is characterized by the power spectrum of the fluctuations &amp;lt;math&amp;gt;\tilde{S}(q,\omega)&amp;lt;/math&amp;gt;, &lt;br /&gt;
which is determined by &amp;lt;math&amp;gt;J(\omega)&amp;lt;/math&amp;gt; and by the assumed interaction &amp;lt;math&amp;gt;u(r)&amp;lt;/math&amp;gt;. See [[The_dephasing_rate_SP_formula#Example|examples]].&lt;br /&gt;
&lt;br /&gt;
The model can be used to describes the dynamics of a Brownian particle in an Ohmic environment whose fluctuations are uncorrelated in space.&amp;lt;ref&amp;gt;D. Cohen, J. Phys. A 31, 8199 (1998)&amp;lt;/ref&amp;gt;&lt;br /&gt;
&amp;lt;ref&amp;gt;&#039;&#039;Driven chaotic mesoscopic systems,dissipation and decoherence&#039;&#039;,&lt;br /&gt;
in Proceedings of the 38th Karpacz Winter School of Theoretical Physics, Edited by P. Garbaczewski and R. Olkiewicz (Springer, 2002). http://arxiv.org/abs/quant-ph/0403061&amp;lt;/ref&amp;gt; This should be contrasted with the Zwanzig-Caldeira-Leggett model, where the induced fluctuating force is assumed to be uniform in space (see figure).&lt;br /&gt;
&lt;br /&gt;
At high temperatures the propagator possess a Markovian property and one can write down an equivalent Master equation. Unlike the case of the Zwanzig-Caldeira-Leggett model, genuine quantum mechanical effects manifest themselves due to the disordered nature of the environment.&lt;br /&gt;
&lt;br /&gt;
Using Wigner picture of the dynamics one can distinguish between two different mechanisms for destruction of coherence: scattering mechanism and smearing mechanism. The analysis of [[dephasing]] can be extended to the low temperature regime by using a semiclassical strategy. &lt;br /&gt;
In this context [[the dephasing rate SP formula]] can be derived.&lt;br /&gt;
&amp;lt;ref&amp;gt;D. Cohen and Y. Imry, Phys. Rev. B 59, 11143 (1999)&amp;lt;/ref&amp;gt;&lt;br /&gt;
&amp;lt;ref&amp;gt;D. Cohen, J. von Delft, F. Marquardt and Y. Imry, Phys. Rev. B 80, 245410 (2009)&amp;lt;/ref&amp;gt; &lt;br /&gt;
Various results can be derived for ballistic, chaotic, diffusive, both ergodic and non-ergodic motion.&lt;br /&gt;
&lt;br /&gt;
==See also==&lt;br /&gt;
&lt;br /&gt;
* [[Quantum dissipation]]&lt;br /&gt;
* [[dephasing]]&lt;br /&gt;
* [[The dephasing rate SP formula]]&lt;br /&gt;
&lt;br /&gt;
==References==&lt;br /&gt;
{{reflist}}&lt;br /&gt;
&lt;br /&gt;
[[Category:Quantum mechanics]]&lt;/div&gt;</summary>
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